Disturbance rejection and performance analysis for nonlinear systems based on nonlinear equivalent-input-disturbance approach

Xiang Yin; Jinhua She; Min Wu; Daiki Sato; Kaoru Hirota

doi:10.1007/s11071-020-05699-z

Disturbance rejection and performance analysis for nonlinear systems based on nonlinear equivalent-input-disturbance approach

Xiang Yin, Jinhua She^*, Min Wu, Daiki Sato, Kaoru Hirota

^*Corresponding author for this work

School of Automation

Research output: Contribution to journal › Article › peer-review

22 Citations (Scopus)

Abstract

This paper presents a nonlinear equivalent-input-disturbance (NEID) approach to rejecting an unknown exogenous disturbance in a nonlinear system. An NEID compensator has two parts: a conventional equivalent-input-disturbance estimator and a nonlinear state feedback term. This design ensures that only the exogenous disturbance is rejected and the useful nonlinearity of the system is retained. Unlike other active disturbance-rejection methods, a Lipschitz condition is not necessary to guarantee the convergence of the observation error. Analysis of control performance provides upper bounds for the evaluation of disturbance rejection and the degree of nonlinearity retention. Numerical examples show the validity and superiority of this method.

Original language	English
Pages (from-to)	3497-3511
Number of pages	15
Journal	Nonlinear Dynamics
Volume	100
Issue number	4
DOIs	https://doi.org/10.1007/s11071-020-05699-z
Publication status	Published - 1 Jun 2020

Keywords

Equivalent input disturbance
Exogenous disturbance estimation
Local uniformly boundedness
Nonlinear system
Performance analysis

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abstract = "This paper presents a nonlinear equivalent-input-disturbance (NEID) approach to rejecting an unknown exogenous disturbance in a nonlinear system. An NEID compensator has two parts: a conventional equivalent-input-disturbance estimator and a nonlinear state feedback term. This design ensures that only the exogenous disturbance is rejected and the useful nonlinearity of the system is retained. Unlike other active disturbance-rejection methods, a Lipschitz condition is not necessary to guarantee the convergence of the observation error. Analysis of control performance provides upper bounds for the evaluation of disturbance rejection and the degree of nonlinearity retention. Numerical examples show the validity and superiority of this method.",

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AU - She, Jinhua

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AU - Sato, Daiki

AU - Hirota, Kaoru

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AB - This paper presents a nonlinear equivalent-input-disturbance (NEID) approach to rejecting an unknown exogenous disturbance in a nonlinear system. An NEID compensator has two parts: a conventional equivalent-input-disturbance estimator and a nonlinear state feedback term. This design ensures that only the exogenous disturbance is rejected and the useful nonlinearity of the system is retained. Unlike other active disturbance-rejection methods, a Lipschitz condition is not necessary to guarantee the convergence of the observation error. Analysis of control performance provides upper bounds for the evaluation of disturbance rejection and the degree of nonlinearity retention. Numerical examples show the validity and superiority of this method.

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Disturbance rejection and performance analysis for nonlinear systems based on nonlinear equivalent-input-disturbance approach

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Keywords

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